Interference cancellation in respiratory sounds via a multiresolution joint time-delay and signal-estimation scheme

As respiratory sounds contain mechanical and clinical pulmonary information, technical efforts have been devoted during the past decades to analysing, processing and visualising them. The aim of this work was to evaluate deterministic interpolating functions to generate surface respiratory acoustic thoracic images (RATHIs), based on multiple acoustic sensors. Lung sounds were acquired from healthy subjects through a 5 x 5 microphone array on the anterior and posterior thoracic surfaces. The performance of five interpolating functions, including the linear, cubic spline, Hermite, Lagrange and nearest neighbour method, were evaluated to produce images of lung sound intensity during both breathing phases, at low (approximately 0.5ls(-1)) and high (approximately 1.0ls(-1)) airflows. Performance indexes included the normalised residual variance nrv (i.e. inaccuracy), the prediction covariance cv (i.e. precision), the residual covariance rcv (i.e. bias) and the maximum squared residual error semax (i.e. tolerance). Among the tested interpolating functions and in all experimental conditions, the Hermite function (nrv=0.146 +/- 0.059, cv= 0.925 +/- 0.030, rcv = -0.073 +/- 0.068, semax = 0.005 +/- 0.004) globally provided the indexes closest to the optimum, whereas the nearest neighbour (nrv=0.339 +/- 0.023, cv = 0.870 +/- 0.033, rcv= 0.298 +/- 0.032, semax = 0.007 +/- 0.005) and the Lagrange methods (nrv = 0.287 +/- 0.148, cv = 0.880 +/- 0.039, rcv = -0.524 +/- 0.135, semax = 0.007 +/- 0.0001) presented the poorest statistical measurements. It is concluded that, although deterministic interpolation functions indicate different performances among tested techniques, the Hermite interpolation function presents a more confident deterministic interpolation for depicting surface-type RATHI.

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“…Therefore it seems necessary to enhance the SNR of the LS signals by cancelling the heart sounds and other interference (CHARLESTON et al, 1997).…”

Section: Discussionmentioning

confidence: 99%

Respiratory acoustic thoracic imaging (RATHI): Assessing deterministic interpolation techniques

Charleston-Villalobos

Cortés-Rubiano

González-Camerena

et al. 2004

Med. Biol. Eng. Comput.

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“…An observed signal is a projection from this multivariate state space onto a one-dimensional time series. can be considered as a set of scalar measurements (1) from which a sequence of -dimensional vectors can be constructed using Takens' delay embedding theorem (2) where is a delay parameter, and is the embedding dimension [9]. The purpose of the embedding is to unfold the projection back into a reconstructed state space that is dynamically and topologically equivalent to the state space that generated the process [10].…”

Section: A State-space Reconstructionmentioning

confidence: 99%

“…The latter sounds can be reduced with adequate and firm microphone placement and by using sound proof rooms, but HS noise is unavoidable. HS and LS have overlapping frequency spectra, and even though highpass filtering is often employed to reduce HS, this results in loss of important signal information [2]. Previous approaches to HS cancellation from recorded LS include wavelet-based methods [2], adaptive filtering techniques [3], and fourth-order statistics [4], all resulting in reduced but still audible HS.…”

Section: Introductionmentioning

confidence: 99%

“…HS and LS have overlapping frequency spectra, and even though highpass filtering is often employed to reduce HS, this results in loss of important signal information [2]. Previous approaches to HS cancellation from recorded LS include wavelet-based methods [2], adaptive filtering techniques [3], and fourth-order statistics [4], all resulting in reduced but still audible HS. Recent studies indicate that cutting out segments containing HS followed by interpolation of the missing data yields promising results [5], [6].…”

Section: Introductionmentioning

confidence: 99%

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Heart sound cancellation from lung sound recordings using recurrence time statistics and nonlinear prediction

Ahlström

Liljefeldt

Hult

et al. 2005

IEEE Signal Process. Lett.

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Heart sounds (HS) obscure the interpretation of lung sounds (LS). This letter presents a new method to detect and remove this undesired disturbance. The HS detection algorithm is based on a recurrence time statistic that is sensitive to changes in a reconstructed state space. Signal segments that are found to contain HS are removed, and the arising missing parts are replaced with predicted LS using a nonlinear prediction scheme. The prediction operates in the reconstructed state space and uses an iterated integrated nearest trajectory algorithm. The HS detection algorithm detects HS with an error rate of 4% false positives and 8% false negatives. The spectral difference between the reconstructed LS signal and an LS signal with removed HS was 0.34/spl plusmn/0.25, 0.50/spl plusmn/0.33, 0.46/spl plusmn/0.35, and 0.94/spl plusmn/0.64 dB/Hz in the frequency bands 20-40, 40-70, 70-150, and 150-300 Hz, respectively. The cross-correlation index was found to be 99.7%, indicating excellent similarity between actual LS and predicted LS. Listening tests performed by a skilled physician showed high-quality auditory results.Original publication: Ahlstrom, C., Liljefeldt, O., Hult, P. and Ask, P., Heart sound cancellation from lung sound recordings using recurrence time statistics and nonlinear prediction, 2005, IEEE Signal Processing Letters, (12), 12, 812-815. http://dx.doi.org/10.1109/LSP.2005.859528. Copyright: IEEE, http://ieeexplore.ieee.org/xpl/RecentIssue.jsp?punumber=9

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“…Several different techniques have been implemented to remove (reduce) the level of respiratory sound signals (RSSs) within total sound recording. High pass filtering [1], wavelet based methods [2], adaptive filtering techniques [3], fourthorder statistics [4]. Promising results can be achieved by cutting out heart sound segments and interpolating the missing data [5] and two-channel handling of lung sound [6].…”

Section: Introductionmentioning

confidence: 99%

Separating heart sound from lung sound using Non-Local Means filter

Rudnitskii

2014

2014 IEEE 34th International Scientific Conference on Electronics and Nanotechnology (ELNANO)

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Primary aim of this work is to develop methodology for extracting useful information from the phonocardiographic signal for a computerized cardiac auscultation system and the intelligent stethoscope. The paper presents a technique based on a Non-Local Means method (NLM). When synthetic data is combined with the heart sound signal, it is found that NLM can separate the heart sound without degrading the main characteristic features of heart sound at wide diapason of signal-to-noise ratio (SNRin). The results of application of NLM to real auscultation signal are also promising.

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Interference cancellation in respiratory sounds via a multiresolution joint time-delay and signal-estimation scheme

Cited by 21 publications

References 20 publications

Respiratory acoustic thoracic imaging (RATHI): Assessing deterministic interpolation techniques

Respiratory acoustic thoracic imaging (RATHI): Assessing deterministic interpolation techniques

Heart sound cancellation from lung sound recordings using recurrence time statistics and nonlinear prediction

Separating heart sound from lung sound using Non-Local Means filter

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